Human voltage-gated Na+ and K+ channel properties underlie sustained fast AP signaling

René Wilbers; Verjinia D. Metodieva; Sarah Duverdin; Djai B. Heyer; Anna A. Galakhova; Eline J. Mertens; Tamara D. Versluis; Johannes C. Baayen; Sander Idema; David P. Noske; Niels Verburg; Ronald B. Willemse; Philip C. de Witt Hamer; Maarten H. P. Kole; Christiaan P. J. de Kock; Huibert D. Mansvelder; Natalia A. Goriounova

doi:https://doi.org/10.1126/sciadv.ade3300

Human voltage-gated Na+ and K+ channel properties underlie sustained fast AP signaling

René Wilbers, Verjinia D. Metodieva, Sarah Duverdin, Djai B. Heyer, Anna A. Galakhova, Eline J. Mertens, Tamara D. Versluis, Johannes C. Baayen, Sander Idema, David P. Noske, Niels Verburg, Ronald B. Willemse, Philip C. de Witt Hamer, Maarten H. P. Kole, Christiaan P. J. de Kock, Huibert D. Mansvelder, Natalia A. Goriounova

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Abstract

Human cortical pyramidal neurons are large, have extensive dendritic trees, and yet have unexpectedly fast input-output properties: Rapid subthreshold synaptic membrane potential changes are reliably encoded in timing of action potentials (APs). Here, we tested whether biophysical properties of voltage-gated sodium (Na+) and potassium (K+) currents in human pyramidal neurons can explain their fast input-output properties. Human Na+ and K+ currents exhibited more depolarized voltage dependence, slower inactivation, and faster recovery from inactivation compared with their mouse counterparts. Computational modeling showed that despite lower Na+ channel densities in human neurons, the biophysical properties of Na+ channels resulted in higher channel availability and contributed to fast AP kinetics stability. Last, human Na+ channel properties also resulted in a larger dynamic range for encoding of subthreshold membrane potential changes. Thus, biophysical adaptations of voltage-gated Na+ and K+ channels enable fast input-output properties of large human pyramidal neurons.

Original language	English
Pages (from-to)	eade3300
Journal	Science advances
Volume	9
Issue number	41
DOIs	https://doi.org/10.1126/sciadv.ade3300
Publication status	Published - 13 Oct 2023

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Wilbers, R., Metodieva, V. D., Duverdin, S., Heyer, D. B., Galakhova, A. A., Mertens, E. J., Versluis, T. D., Baayen, J. C., Idema, S., Noske, D. P., Verburg, N., Willemse, R. B., de Witt Hamer, P. C., Kole, M. H. P., de Kock, C. P. J., Mansvelder, H. D., & Goriounova, N. A. (2023). Human voltage-gated Na+ and K+ channel properties underlie sustained fast AP signaling. Science advances, 9(41), eade3300. https://doi.org/10.1126/sciadv.ade3300

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title = "Human voltage-gated Na+ and K+ channel properties underlie sustained fast AP signaling",

abstract = "Human cortical pyramidal neurons are large, have extensive dendritic trees, and yet have unexpectedly fast input-output properties: Rapid subthreshold synaptic membrane potential changes are reliably encoded in timing of action potentials (APs). Here, we tested whether biophysical properties of voltage-gated sodium (Na+) and potassium (K+) currents in human pyramidal neurons can explain their fast input-output properties. Human Na+ and K+ currents exhibited more depolarized voltage dependence, slower inactivation, and faster recovery from inactivation compared with their mouse counterparts. Computational modeling showed that despite lower Na+ channel densities in human neurons, the biophysical properties of Na+ channels resulted in higher channel availability and contributed to fast AP kinetics stability. Last, human Na+ channel properties also resulted in a larger dynamic range for encoding of subthreshold membrane potential changes. Thus, biophysical adaptations of voltage-gated Na+ and K+ channels enable fast input-output properties of large human pyramidal neurons.",

author = "Ren{\'e} Wilbers and Metodieva, {Verjinia D.} and Sarah Duverdin and Heyer, {Djai B.} and Galakhova, {Anna A.} and Mertens, {Eline J.} and Versluis, {Tamara D.} and Baayen, {Johannes C.} and Sander Idema and Noske, {David P.} and Niels Verburg and Willemse, {Ronald B.} and {de Witt Hamer}, {Philip C.} and Kole, {Maarten H. P.} and {de Kock}, {Christiaan P. J.} and Mansvelder, {Huibert D.} and Goriounova, {Natalia A.}",

year = "2023",

month = oct,

day = "13",

doi = "https://doi.org/10.1126/sciadv.ade3300",

language = "English",

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journal = "Science advances",

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Wilbers, R, Metodieva, VD, Duverdin, S, Heyer, DB, Galakhova, AA, Mertens, EJ, Versluis, TD, Baayen, JC, Idema, S , Noske, DP , Verburg, N , Willemse, RB , de Witt Hamer, PC, Kole, MHP, de Kock, CPJ, Mansvelder, HD & Goriounova, NA 2023, 'Human voltage-gated Na+ and K+ channel properties underlie sustained fast AP signaling', Science advances, vol. 9, no. 41, pp. eade3300. https://doi.org/10.1126/sciadv.ade3300

TY - JOUR

T1 - Human voltage-gated Na+ and K+ channel properties underlie sustained fast AP signaling

AU - Wilbers, René

AU - Metodieva, Verjinia D.

AU - Duverdin, Sarah

AU - Heyer, Djai B.

AU - Galakhova, Anna A.

AU - Mertens, Eline J.

AU - Versluis, Tamara D.

AU - Baayen, Johannes C.

AU - Idema, Sander

AU - Noske, David P.

AU - Verburg, Niels

AU - Willemse, Ronald B.

AU - de Witt Hamer, Philip C.

AU - Kole, Maarten H. P.

AU - de Kock, Christiaan P. J.

AU - Mansvelder, Huibert D.

AU - Goriounova, Natalia A.

PY - 2023/10/13

Y1 - 2023/10/13

N2 - Human cortical pyramidal neurons are large, have extensive dendritic trees, and yet have unexpectedly fast input-output properties: Rapid subthreshold synaptic membrane potential changes are reliably encoded in timing of action potentials (APs). Here, we tested whether biophysical properties of voltage-gated sodium (Na+) and potassium (K+) currents in human pyramidal neurons can explain their fast input-output properties. Human Na+ and K+ currents exhibited more depolarized voltage dependence, slower inactivation, and faster recovery from inactivation compared with their mouse counterparts. Computational modeling showed that despite lower Na+ channel densities in human neurons, the biophysical properties of Na+ channels resulted in higher channel availability and contributed to fast AP kinetics stability. Last, human Na+ channel properties also resulted in a larger dynamic range for encoding of subthreshold membrane potential changes. Thus, biophysical adaptations of voltage-gated Na+ and K+ channels enable fast input-output properties of large human pyramidal neurons.

AB - Human cortical pyramidal neurons are large, have extensive dendritic trees, and yet have unexpectedly fast input-output properties: Rapid subthreshold synaptic membrane potential changes are reliably encoded in timing of action potentials (APs). Here, we tested whether biophysical properties of voltage-gated sodium (Na+) and potassium (K+) currents in human pyramidal neurons can explain their fast input-output properties. Human Na+ and K+ currents exhibited more depolarized voltage dependence, slower inactivation, and faster recovery from inactivation compared with their mouse counterparts. Computational modeling showed that despite lower Na+ channel densities in human neurons, the biophysical properties of Na+ channels resulted in higher channel availability and contributed to fast AP kinetics stability. Last, human Na+ channel properties also resulted in a larger dynamic range for encoding of subthreshold membrane potential changes. Thus, biophysical adaptations of voltage-gated Na+ and K+ channels enable fast input-output properties of large human pyramidal neurons.

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SN - 2375-2548

VL - 9

SP - eade3300

JO - Science advances

JF - Science advances

IS - 41

ER -

Human voltage-gated Na+ and K+ channel properties underlie sustained fast AP signaling

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